In graph theory, two graphs G and G' are homeomorphic if there is a graph isomorphism from some subdivision of G to some subdivision of G'. If the edges of a graph are thought of as lines drawn from one vertex to another (as they are usually depicted in diagrams), then two graphs are homeomorphic to each other in the graph-theoretic sense precisely if their diagrams are homeomorphic in the topological sense.

Subdivision and smoothing

In general, a subdivision of a graph G (sometimes known as an expansion ) is a graph resulting from the subdivision of edges in G. The subdivision of some edge e with endpoints {u,v } yields a graph containing one new vertex w, and with an edge set replacing e by two new edges, {u,w } and {w,v }. For directed edges, this operation shall reserve their propagating direction. For example, the edge e, with endpoints {u,v }: can be subdivided into two edges, e1 and e2, connecting to a new vertex w of degree-2, or indegree-1 and outdegree-1 for the directed edge: Determining whether for graphs G and H, H is homeomorphic to a subgraph of G, is an NP-complete problem.

Reversion

The reverse operation, smoothing out or smoothing a vertex w with regards to the pair of edges (e1, e2) incident on w, removes both edges containing w and replaces (e1, e2) with a new edge that connects the other endpoints of the pair. Here, it is emphasized that only degree-2 (i.e., 2-valent) vertices can be smoothed. The limit of this operation is realized by the graph that has no more degree-2 vertices. For example, the simple connected graph with two edges, e1 {u,w } and e2 {w,v }: has a vertex (namely w) that can be smoothed away, resulting in:

Barycentric subdivisions

The barycentric subdivision subdivides each edge of the graph. This is a special subdivision, as it always results in a bipartite graph. This procedure can be repeated, so that the nth barycentric subdivision is the barycentric subdivision of the n−1st barycentric subdivision of the graph. The second such subdivision is always a simple graph.

Embedding on a surface

It is evident that subdividing a graph preserves planarity. Kuratowski's theorem states that In fact, a graph homeomorphic to K5 or K3,3 is called a Kuratowski subgraph. A generalization, following from the Robertson–Seymour theorem, asserts that for each integer g, there is a finite obstruction set of graphs such that a graph H is embeddable on a surface of genus g if and only if H contains no homeomorphic copy of any of the. For example, consists of the Kuratowski subgraphs.

Example

In the following example, graph G and graph H are homeomorphic. If G′ is the graph created by subdivision of the outer edges of G and H′ is the graph created by subdivision of the inner edge of H, then G′ and H′ have a similar graph drawing: Therefore, there exists an isomorphism between G' and H' , meaning G and H are homeomorphic.

mixed graph

The following mixed graphs are homeomorphic. The directed edges are shown to have an intermediate arrow head.